CA2380575C - Brushless motor - Google Patents

Brushless motor Download PDF

Info

Publication number
CA2380575C
CA2380575C CA2380575A CA2380575A CA2380575C CA 2380575 C CA2380575 C CA 2380575C CA 2380575 A CA2380575 A CA 2380575A CA 2380575 A CA2380575 A CA 2380575A CA 2380575 C CA2380575 C CA 2380575C
Authority
CA
Canada
Prior art keywords
rotor
brushless motor
windings
permanent magnets
stator
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Expired - Lifetime
Application number
CA2380575A
Other languages
French (fr)
Other versions
CA2380575A1 (en
Inventor
Kenji Fujiwara
Akira Nishio
Yoshiki Kato
Masahiro Hirano
Takatoshi Kogure
Tsutomu Baba
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Mitsubishi Heavy Industries Ltd
Original Assignee
Mitsubishi Heavy Industries Ltd
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Priority claimed from JP2000166119A external-priority patent/JP2001352727A/en
Priority claimed from JP2000347662A external-priority patent/JP2002153033A/en
Application filed by Mitsubishi Heavy Industries Ltd filed Critical Mitsubishi Heavy Industries Ltd
Publication of CA2380575A1 publication Critical patent/CA2380575A1/en
Application granted granted Critical
Publication of CA2380575C publication Critical patent/CA2380575C/en
Anticipated expiration legal-status Critical
Expired - Lifetime legal-status Critical Current

Links

Classifications

    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02KDYNAMO-ELECTRIC MACHINES
    • H02K21/00Synchronous motors having permanent magnets; Synchronous generators having permanent magnets
    • H02K21/12Synchronous motors having permanent magnets; Synchronous generators having permanent magnets with stationary armatures and rotating magnets
    • H02K21/14Synchronous motors having permanent magnets; Synchronous generators having permanent magnets with stationary armatures and rotating magnets with magnets rotating within the armatures
    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02KDYNAMO-ELECTRIC MACHINES
    • H02K1/00Details of the magnetic circuit
    • H02K1/06Details of the magnetic circuit characterised by the shape, form or construction
    • H02K1/22Rotating parts of the magnetic circuit
    • H02K1/27Rotor cores with permanent magnets
    • H02K1/2706Inner rotors
    • H02K1/2713Inner rotors the magnetisation axis of the magnets being axial, e.g. claw-pole type
    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02KDYNAMO-ELECTRIC MACHINES
    • H02K1/00Details of the magnetic circuit
    • H02K1/06Details of the magnetic circuit characterised by the shape, form or construction
    • H02K1/22Rotating parts of the magnetic circuit
    • H02K1/27Rotor cores with permanent magnets
    • H02K1/2706Inner rotors
    • H02K1/272Inner rotors the magnetisation axis of the magnets being perpendicular to the rotor axis
    • H02K1/274Inner rotors the magnetisation axis of the magnets being perpendicular to the rotor axis the rotor consisting of two or more circumferentially positioned magnets
    • H02K1/2753Inner rotors the magnetisation axis of the magnets being perpendicular to the rotor axis the rotor consisting of two or more circumferentially positioned magnets the rotor consisting of magnets or groups of magnets arranged with alternating polarity
    • H02K1/276Magnets embedded in the magnetic core, e.g. interior permanent magnets [IPM]
    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02KDYNAMO-ELECTRIC MACHINES
    • H02K21/00Synchronous motors having permanent magnets; Synchronous generators having permanent magnets
    • H02K21/12Synchronous motors having permanent magnets; Synchronous generators having permanent magnets with stationary armatures and rotating magnets
    • H02K21/14Synchronous motors having permanent magnets; Synchronous generators having permanent magnets with stationary armatures and rotating magnets with magnets rotating within the armatures
    • H02K21/16Synchronous motors having permanent magnets; Synchronous generators having permanent magnets with stationary armatures and rotating magnets with magnets rotating within the armatures having annular armature cores with salient poles
    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02KDYNAMO-ELECTRIC MACHINES
    • H02K29/00Motors or generators having non-mechanical commutating devices, e.g. discharge tubes or semiconductor devices
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B60VEHICLES IN GENERAL
    • B60LPROPULSION OF ELECTRICALLY-PROPELLED VEHICLES; SUPPLYING ELECTRIC POWER FOR AUXILIARY EQUIPMENT OF ELECTRICALLY-PROPELLED VEHICLES; ELECTRODYNAMIC BRAKE SYSTEMS FOR VEHICLES IN GENERAL; MAGNETIC SUSPENSION OR LEVITATION FOR VEHICLES; MONITORING OPERATING VARIABLES OF ELECTRICALLY-PROPELLED VEHICLES; ELECTRIC SAFETY DEVICES FOR ELECTRICALLY-PROPELLED VEHICLES
    • B60L2220/00Electrical machine types; Structures or applications thereof
    • B60L2220/10Electrical machine types
    • B60L2220/14Synchronous machines
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02TCLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO TRANSPORTATION
    • Y02T10/00Road transport of goods or passengers
    • Y02T10/60Other road transportation technologies with climate change mitigation effect
    • Y02T10/64Electric machine technologies in electromobility

Landscapes

  • Engineering & Computer Science (AREA)
  • Power Engineering (AREA)
  • Permanent Field Magnets Of Synchronous Machinery (AREA)
  • Permanent Magnet Type Synchronous Machine (AREA)
  • Brushless Motors (AREA)
  • Synchronous Machinery (AREA)

Abstract

A brushless motor capable of increasing energy density by effective utilization of reluctance torque. The brushless motor comprises a stator (5) and a rotor (1) having a lateral surface opposed to the stator (5). The stator (5) comprises a plurality of radially extending iron cores (10) and a plurality of windings (11) for generating a magnetic field in each iron core (10). The rotor (1) comprises a plurality of permanent magnets (2) and a magnetic field line inducing body disposed between each permanent magnet (2) and the lateral surface.

Description

DESCRIPTION
BRUSHLESS MOTOR
Technical Field The present invention relates to a brushless motor. More particularly, the present invention relates to a brushless motor used as a driving source of an industry robot, a machine tool, an electric car or an electric train.
Background Technique In order to miniaturize a motor and to increase output power and torque thereof, it is important that an energy density Edc is high, which implies a ratio of the volume of the motor to the output power. Moreover, in order to simplify the structure of the motor, it is important to minimize the number of slots for a winding arrangement and make a working efficiency of a winding operation higher.

Such a brushless motor is disclosed in Japanese Laid Open Patent Application (JP-A-Heisei, 11-98791). As shown in Fig. 1, the known brushless motor is a surface magnet type brushless DC motor including 14 poles and 12 slots. The brushless motor is provided with: a
- 2 -group of permanent magnets 102 placed on a cylindrical surface of a rotor 101 in which 14 poles are arranged in series; and a stator 104 in which 12 slots 103-1 to 103-12 are radially placed on the same circumference at a same angular interval. One set of windings 105-U1, 105-V1 and 105-W1 and another set of windings 105-U2, 105-V2 and 105-W2, which respectively positionally correspond to each other, are placed at positions in which phases are mutually shifted counter-clockwise by an electric angle of 120 degrees, in six pairs of slots, each of which is composed of two slots adjacent to each other, among 12 slots 103-1 to 103-12. Moreover, six windings 105-U1', 105-V1', 105-W1', 105-U2', 105-V2' and 105-W2' are respectively placed such that they are shifted by a rotational angle of 30 degrees with respect to the six windings 105-U1, 105-V1, 105-W1, 105-U2, 105-V2 and 105-W2. A U-phase voltage having a phase of 0 is provided for the winding 105-U1 and the windings 105-U2, 105-U1' and 105-U2'. A V-phase voltage having a phase delayed by about 120 degrees from that of the U-phase voltage is provided for the windings 105-V1, 105-V2, 105-V1' and 105-V2'. A W-phase voltage having a phase delayed by about 120 degrees from that of the V-phase voltage is provided for the
3 -windings 105-W1, 105-W2, 105-W1' and 105-W2'.
An output torque T of the known brushless motor is given by the following equation:

T = p{4- I. - cos (R) + (Lq - Ld)Ia2 . sin(2(3)/2).
"' (1) Here, p: Number of Pole Pairs (Number of Poles /2) Maximum armature flux linkage of the permanent magnet Ia: Armature current 3: Phase of armature current Ld: Direct-axis inductance (Inductance in the d-axis direction) Lq: Quadrature-axis inductance (Inductance in the q-axis Direction) The phase of the armature current is defined under the assumption that the phase of the U-phase voltage is 0. The first term on the right side of the equation (1) represents a magnet torque, and the second term on the right side represents a reluctance torque.

In the above-mentioned surface magnet type brushless motor, in which the permanent magnet is placed on the surface of an iron core 101, the following equation:

Lq = Ld , ( 2 )
4 -can be established from the property of that structure.
Here, the symbol indicates that the Lq is approximately (substantially or nearly) equal to the Ld.

Thus, the output torque of the surface magnet type brushless motor is substantially given by the following equation:

T = p I,,- cos Accordingly, the output component represented by the second term on the right side of the previous equation is 0. That component is not outputted. The surface magnet type brushless motor can effectively use only the magnet torque indicated by the first term on the right side of the equation (1). Hence, the increase in the energy density is suppressed.

It is desirable to increase the energy density by effectively using the reluctance torque indicated by the second term on the right side of the equation (1).

Disclosure of Invention In accordance with an aspect of the present invention, there is provided a brushless motor comprising: a stator having a plurality of radially extending iron cores and twelve windings for respectively generating magnetic fields in the iron cores; and a rotor having a lateral surface - 4a -opposed to the stator, the rotor further comprising fourteen permanent magnets each of the permanent magnets having a shape of a substantially rectangular parallelepiped; and magnetic force line induction bodies located between the permanent magnets and the lateral surface, wherein a distance (d) between the center of the rotor and magnetic pole surfaces opposed to the lateral surface among surfaces of the permanent magnets satisfies the following equation:
d > r - D/10, where D = 2nr / P, r: radius of the rotor, and P: number of permanent magnets.

In accordance with another aspect of the present invention, there is provided a brushless motor comprising: a stator; and a rotor having a lateral surface opposed to the stator, wherein the stator includes: a plurality of radially extending iron cores, and a plurality of windings for respectively generating magnetic fields in the iron cores, wherein the rotor includes: a plurality of permanent magnets, and magnetic force line induction bodies located between the permanent magnets and the lateral surface, and wherein a number of the windings is N, and a number of the permanent magnets is P, and P is greater than N.

- 4b -In accordance with another aspect of the present invention, there is provided a brushless motor comprising: a stator; and a rotor having a lateral surface opposed to the stator, wherein the stator includes: a plurality of radially extending iron cores, and a plurality of windings for respectively generating magnetic fields in the iron cores, wherein the rotor includes: a plurality of permanent magnets, and magnetic force line induction bodies located between the permanent magnets and the lateral surface, and wherein an output torque T of the brushless motor is given by a following equation:

T=p {c~=Ia=cos ((3)+(Lq Ld) I'2=sin(2p)/21, p being a half of a number of the plurality of permanent magnets, being a maximum armature flux linkage generated by the plurality of permanent magnets, Ia being an armature current, R being a phase of the armature current, L. being a direct-axis inductance of the rotor, and Lq being a quadrature-axis inductance of the rotor, while the following equation:

LgzLd, does not hold.

In accordance with another aspect of the present invention, there is provided a brushless motor comprising: a stator; and a rotor having a lateral surface opposed to the - 4c -stator, wherein the stator includes: a plurality of radially extending iron cores, and a plurality of windings for respectively generating magnetic fields in the iron cores, wherein the rotor includes: a plurality of permanent magnets, and magnetic force line induction bodies located between the permanent magnets and the lateral surface, wherein three-phase direct currents are provided for the plurality of windings, wherein the windings include: a first group of three-phase windings, and a second group of three-phase windings, and wherein windings having the same phase of the first and second groups of three-phase windings are adjacent to each other in the same rotation direction, and wherein the first group of three-phase windings include: a first set of three-phase windings, and a second set of three-phase windings, and the first set of three-phase windings and the second set of three-phase windings are arranged to be approximately geometrically symmetrical with respect to a line, the second group of three-phase windings include another first set of three-phase windings and another second set of three-phase windings, and the other first set of three-phase windings and the other second set of three-phase windings are arranged to be approximately geometrically symmetrical with respect to a line.

In accordance with another aspect of the present invention, there is provided a brushless motor comprising: a - 4d -stator; and a rotor having a lateral surface opposed to the stator, wherein the stator includes: a plurality of radially extending iron cores, and a plurality of windings for respectively generating magnetic fields in the iron cores, wherein the rotor includes: a plurality of permanent magnets, and magnetic force line induction bodies located between the permanent magnets and the lateral surface, and wherein the permanent magnet has a shape of a substantially rectangular parallelepiped, and a distance between a center of the rotor and magnetic pole surfaces opposed to the lateral surface among surfaces of the plurality of permanent magnets satisfies a following equation:

d z r - D/10, where D = nr/P, r being a radius of the rotor, and P is a number of the permanent magnets.

In accordance with another aspect of the present invention, there is provided a brushless motor comprising: a stator; and a rotor having a lateral surface opposed to the stator, wherein the stator includes: a plurality of radially extending iron cores, and a plurality of windings for respectively generating magnetic fields in the iron cores, wherein the rotor includes: a plurality of permanent magnets, and magnetic force line induction bodies located - 4e -between the permanent magnets and the lateral surface, and wherein a following equation:

0 < (Lq Ld) /Ld 5 0.3, holds, where Lq is a quadrature-axis inductance of the rotor, and L. is a direct-axis inductance of the rotor.

Therefore, an object of the present invention is to provide a brushless motor in which the energy density is increased by effectively using the reluctance torque.

Another object of the present invention is
- 5 -to suppress a torque ripple of the brushless motor.

Still another object of the present invention is to reduce an armature current of the brushless motor.

Still another object of the present invention is to decrease a supply voltage to be provided for the brushless motor.

Still another object of the present invention is to miniaturize the brushless motor.
In order to attain the objects of the present invention, the brushless motor includes a stator and a rotor having a lateral surface opposed to the stator. The stator has a plurality of radially extending iron cores and a plurality of windings for generating magnet fields in the respective iron cores. The rotor includes a plurality of permanent magnets and magnet force line inducing bodies located between the permanent magnets and the lateral surface.

Here, it is desirable that an output torque T is given by the following equation:

T = p{~= I,' cos ((3) + (Lq - La)Iaz sin(2p)/2), where p: Number of Pole Pairs (Number of Poles /2) ~: Maximum armature flux linkage
6 -of the permanent magnet Ia: Armature current 13: Phase of armature current Ld: Direct-axis inductance (Inductance in the d-axis direction) Lq: Quadrature-axis inductance (Inductance in the q-axis Direction) while the following equation:
Lq Ld, does not hold.

Also, it is preferable that the rotor has holes into which the permanent magnets are inserted in the axis direction of the rotor.

Preferably, three-phase direct current is provided for the windings.

Preferably, the windings include a first set of windings and a second set of windings, and the first set of three-phase windings and the second set of three-phase windings are arranged to be symmetrical with respect to a line.
Also, it is preferable that the windings includes a first group of three-phase windings and a second group of three-phase windings, windings having the same phase of the first and second groups of three-phase windings are adjacent to each other in the same rotation direction, the first group of three-phase
7 -windings include a first set of three-phase windings and a second set of three-phase windings, the first set of three-phase windings and the second set of three-phase windings are arranged to be approximately geometrically symmetrical with respect to a line, the second group of three-phase windings include another first set of three-phase windings and another second set three-phase windings, and the other first set three-phase windings and the other second set of three-phase windings are arranged to be approximately geometrically symmetrical with respect to a line.

It is preferable that the number of the windings is N, the number of the permanent magnets is P, and the P is greater than the N.

In this case, it is preferable that one of prime factors of the P is greater than any of prime factors of the N.

It is also preferable that the prime factor of the N has 2 and 3, and the prime factor of the P has 2 and 7.

Also, the P preferable satisfies the following equation:

12 s P s 30.

Preferably, the N is 12, and the P is 14.
Preferably, a section of the permanent
8 -magnet in a flat plane vertical to a central axis of the rotor is rectangular, the rectangle has short sides and long sides longer than the short sides, and the long sides are opposed to the lateral surface.

Preferably, the permanent magnet has a shape of a substantially rectangular parallelepiped, and a distance d between a center of the rotor and a magnetic pole surface opposed to the lateral surface among surfaces of the permanent magnets satisfies the following equation:

d z r - D/10, Here, D = 2nr/P, r: Radius of the rotor, and P: Number of the permanent magnets.
Also, the following equation 0 s ( Lq - Ld) / Ld s 0. 3, preferably holds, where Lq: Quadrature-axis inductance of the rotor, and Ld: Direct-axis inductance of the rotor.
Moreover, it is preferable that the magnetic force line inducting bodies include a direct axis magnetic force line inducting body for inducing magnetic fluxes in the direct axis
9 -direction of the rotor, the magnetic force line inducting bodies having a gap extending in the quadrature axis direction of the rotor.

According to a further aspect of the present invention, there is provided a motor drive vehicle which comprises drive wheels; the brushless motor as defined in the present invention wherein the rotor included in the brushless motor drives the drive wheels; and a power supply voltage supplier for supplying a power supply voltage to the brushless motor.

According to a still further aspect of the present invention there is provided an electric car which comprises drive wheels; the brushless motor as defined in the present invention wherein the rotor included in the brushless motor drives the drive wheels; a power supply voltage supplier for supplying a power supply voltage to the brushless motor, on the basis of a movement of an accelerator pedal.

According to yet another aspect of the present invention there is provided an electric train which comprises drive wheels; the brushless motor as defined in the present invention wherein the rotor included in the brushless motor drives the drive wheels; a power supply voltage supplier for supplying a power supply voltage to the brushless motor, on the basis of a movement of a throttle lever.

- 9a -Brief Description of the Drawings Fig. 1 shows a brushless motor in a first embodiment according to the present invention;

Fig. 2 shows a configuration of the brushless motor in the first embodiment according to the present invention;

Fig. 3 is a graph showing a performance comparison of a brushless motor;

Fig. 4 is another graph showing a performance comparison of a brushless motor;

Fig. 5 shows a configuration of a brushless motor in a second embodiment according to the present invention;

Fig. 6 shows a configuration of a rotor 31;
Fig. 7 is an expanded view showing a part of the rotor 31;

Figs. 8A is a view explaining an effective magnet area rate Mgc;

Figs. 8B is a view explaining an effective magnet area rate Mgc;

Fig. 9 shows a dependency of an effective magnet area rate Mgc and a magnetic flux density Be on a pole number P;
- 10 -Fig. 10 shows a dependency of a q-axis inductance on a pole number P;

Fig. 11 shows a dependency of an armature current Ia on an embedded amount x;

Fig. 12 shows a relation between an embedded amount x and (L q - Ld) / Ld;

Fig. 13 shows a configuration of a brushless motor in a third embodiment;

Fig. 14 is an expanded view showing a configuration of a rotor 31';

Fig. 15 shows an electric car including a brushless motor; and Fig. 16 shows an electric train including a brushless motor.

Preferred Embodiments to Attain Invention (First Embodiment) A brushless motor in the first embodiment is a brushless DC motor driven by a three-phase pulse direct current. The brushless motor has a rotor 1 shown in Fig. 2. The rotor 1 is constituted by a magnetic force line inducing material for inducing a magnetic force line, such as silicon steel or electro-magnetic steel. A 14 permanent magnet 2 is embedded in the rotor 1.
The 14-pole permanent magnet 2 corresponds to 14 permanent magnets. The 14 permanent magnets 2 are
- 11 -inserted and placed in 14 pillar holes 4 opened through the rotor 1 in an axis direction. The pillar holes 4 are trapezoidal on a section orthogonal to the axis. One rectangular bar magnet is pressed to be place in each of the pillar holes 4. A magnetic force line, which is oriented from a South pole to a North pole in each of the permanent magnets 2, is oriented in the axis direction. The directions of the magnetic force lines generated by the two magnets adjacent to each other are opposite to each other.
The 14 permanent magnets 2 are arrayed at the same angle interval (=360Q/14) on the same circumference. The magnetic force lines, generated by the 14 magnets arrayed in the circumference direction as mentioned above, are generated by the synthesis of the magnetic force line oriented in the circumference direction and the magnetic force line oriented in the axis direction.

The rotor 1 has a stator 5 having the structure of a bearing. The stator 5 includes a cylindrical ring iron core 8, iron cores 101 -1012 extending in a radius direction from the ring iron core 8, and windings 111 - 1112. Hereafter, the iron cores 101 - 1012 may be collectively referred to as iron cores 10, and the windings 111
- 12 -- 1112 may be collectively referred to as windings 11. The ring iron core 8 and the iron cores 10 are integrally formed into one unit. There is micro clearance between a cylindrical surface, which is an outer circumference surface of the rotor 1 and an inner surface of the iron core 10 in the radius direction. The iron cores 10 are placed on the same circumference at a same interval (=3600/12). A center of the ring iron core 8 is coincident with a center of the rotor 1.
Twelve slots 91 - 912 are respectively formed between the two iron cores adjacent to each other among the iron cores 10.

The windings 111 - 1112 are respectively wounded around the iron cores 101 - 1012. The three windings 111, 115 , and 1199 of the 12 windings 11 constitute a first set of windings.
The three windings, constituting the first set of windings, are placed on the same circumference at the same interval (=120 = 360 /3). Other three windings 117 , 1111, and 113 of the twelve windings 11 are placed respectively positionally corresponding to the first set windings 111, 115, and 1199 with respect to a line, and they constitute a second set of windings. Here, a center of the line symmetry corresponds to a rotational axis centerline of the rotor 1.
- 13 -The first set winding and the second set winding constitute a first group of windings. The six windings constituting a second group winding are placed respectively adjacently in the same rotation direction in the six windings of the first group winding.

Phases of armature currents provided for the windings 111-1112 are denoted by symbols U, V, W, U', V' and W' shown in Fig. 2. A U-phase armature current is provided for the windings 111, 116, 117, and 1112, a V-phase armature current provided for the windings 114, 115, 1110, and 1111, and a W-phase armature current is provided for the windings 112, 113, 118, and 119. The U-phase armature current, the V-phase armature current and the W-phase armature current are pulse direct currents whose phases are shifted by about 1200 from each other. The temporal intervals of the U-phase, V-phase and W-phase armature currents are controlled, namely, the magnetic field rotation speed is controlled so that the rotor 1 is rotated at any rotationally angular speed.

Also, the directions in which the currents flow through the windings 111 - 1112 are denoted by symbols U, V, W, U', V' and W' in Fig. 2. The directions of the currents denoted by the symbols U, V and W are opposite to the directions of the
- 14 -currents denoted by the symbols U', V' and W', respectively. The currents in the directions opposite to each other when they are viewed from on the same circumference direction line flow through the two windings located symmetrically with respect to the line. For example, the currents in the directions opposite to each other flow through the winding 11, and the winding 11,.
The polarities of the two permanent magnets 2 placed positionally corresponding to a certain rotation angle position, in the two windings having the above-mentioned configuration are opposite to each other. For example, although a South pole of a permanent magnet 21 is oriented in the rotor 1, a North pole of the permanent magnet 28 is oriented in the rotor 1. The armature currents in the directions opposite to each other simultaneously flow through the respective windings of the first group winding and the respective windings of the second group winding which have the same phase and are adjacent to the above-mentioned respective windings. For example, the armature currents in the directions opposite to each other flow through the winding 11, and the winding 1112 In the brushless motor according to the present invention, the fact that an output torque
15 -is larger than that of the known brushless motor is introduced from the equation (1). The equation (1) is as follows:

T p (TM + TO

T. = Ia cOs ((3) , TR = ( Lq - Ld ) I'2 sin(2p)/2 where T. is the magnet torque, and TR is the reluctance torque.

The 14 permanent magnets 21-214 are embedded in the rotor 1 and thus the density of magnetic force lines closed by a magnetic route in the rotor 1 is higher than that of the known motor in Fig. 1. Such difference causes the values of Lq and Ld to be more asymmetrical, which results in the positive establishment of the following equation:

Lq > Ld, (4) Let us compare the known brushless motor with the brushless motor according to the present invention. When the output torque of the known brushless motor is represented by T' and the output torque of the brushless motor according to the present invention is represented by T, the following equation:

T' < T, (5) is established from the condition (4).

Figs. 3, 4 show the performances comparison
- 16 -between the known brushless motor and the brushless motor according to the present invention. Fig. 3 shows the performance comparison with regard to the relation between the rotation speed and the output torque, and Fig.
4 shows the performance comparison with regard to the relation between the rotation speed and the output. In the brushless motor according to the present invention, both the output torque (its unit is Nm) and the output (its unit is J in terms of kW) are greater than those of the known brushless motor.

Moreover, the brushless motor according to the present invention succeeds to the following merits of the known brushless motor in their original states.

(1) The brushless motor has a high winding coefficient and a high energy density.

(2) The number of the slot is reduced, and the productivity efficiency is high.

(3) A cogging torque generation index, namely, the least common multiple of the pole number 14 and the slot number 12 is large, and a torque ripple frequency is increased.

The high torque ripple frequency is effective since it minimizes the influence on a mechanical system, which is usually controlled at
- 17 -a low frequency band.

Moreover, the inner installation of the permanent magnet stimulates the structure of the protruded pole in the magnetic force system so that theLq is not equal to the Ld. Thus, the reluctance torque is effectively used, which leads to the higher energy density, namely, the higher output. Conversely, the miniaturization is possible.

(Second Embodiment) A brushless motor in the second embodiment is a brushless DC motor having the structure similar to that of the brushless motor in the first embodiment. The brushless motor in the second embodiment differs from the brushless motor in the first embodiment in the structure of the rotor. The brushless motor in the second embodiment includes a stator 5 and a rotor 31 as shown in Fig. 5. The structure of the stator 5 is equal to that explained in the first embodiment.
The rotor 31 is opposed to the stator 5 on a rotor side surface 31a. The rotor 31 is rotatably connected to a shaft 32. The rotor 31 is rotated on the shaft 32.

The rotor 31 includes a rotor iron core 33 and 14 permanent magnets 341 - 3414 as shown in
- 18 -Fig. 2. The permanent magnets 341 - 3414 are collectively referred to as permanent magnets 34.
The rotor iron core 33 is formed of laminated silicon steel plates. The respective silicon steel plates are electrically insulated from each other. This reduces the loss by eddy currents. Each of the silicon steel plates is blanked out and provided with holes into which permanent magnets 34 are embedded. The permanent magnets 34 are inserted into the holes. That is, the permanent magnets 34 are embedded in the rotor iron core 33. By the way, the rotor iron core 33 may be made of another material such as electromagnetic steel plates.

Fig. 6 shows the structure in the axis direction of the rotor 31. Fig. 6 shows the structure of the permanent magnet 342 among the permanent magnets 34. The other permanent magnets 34 have the same structure as the permanent magnet 342. Each of the permanent magnets 34 is composed of a plurality of magnets 35 connected in the axis direction of the rotor 31, as shown in Fig. 6. The magnets 35 are electrically insulated from each other. Thus, the loss caused by the eddy currents is suppressed.

The permanent magnets 34 substantially have the shape of a rectangular parallelepiped. The
19 -permanent magnets 34 having the shape of the rectangular parallelepiped are advantageous in that the permanent magnets 34 are easily produced.
In the known brushless motor shown in Fig. 1, permanent magnets having curved surfaces are placed on a side of the rotor 101. The fabrication of permanent magnets having the curved surfaces increases the cost. In the brushless motor in this embodiment, on the other hand, the permanent magnets 34 have the shape of the rectangular parallelepiped, and thus the cost is reduced.

The North poles of the permanent magnets 341, 343, 345, 347, 349, 3411, and 3413 among the permanent magnets 34 are located on the outer side of the rotor 31 in the radius direction, and their South poles are located on the inner side of the rotor 31. On the other hand, the South poles of the permanent magnets 342, 344, 346, 348, 3410, 3412, and 3'413 among the permanent magnets 34 are located on the outer side in the radius direction of the rotor 31, and their North poles are located on the inner side in the radius direction of the rotor 31. That is, the two permanent magnets adjacent to each other among the permanent magnets 34 generate the magnetic force lines in the directions opposite to each
- 20 -other.

Fig. 7 is an expanded view showing a part of the rotor 31. The permanent magnet 34 has an opposing surface 34a opposed to a rotor side surface 31a of the rotor 31 and an opposing surface 34b opposed to a center llb of the rotor 31. The two magnetic poles of the permanent magnets 34 are located on the opposing surfaces 34a, and 34b. The opposing surfaces 34a and 34b forms the long sides of a rectangle formed on a section of the permanent magnet 34 located in a direction vertical to a central axis of the rotor 31.

The permanent magnets 34 are placed in the vicinity of the rotor side surface 31a. The rotor side surface 31a and the permanent magnets 34 are located the closest to each other at end portions 34c. That is, when an embedded amount of the permanent magnet 34 is assumed to be x and a distance between the rotor side surface 31a and the end portions 34c is assumed to be L, the following equation:

x > L, holds. Here, the embedded amount x is defined as the difference between a radius r of the rotor 31 and a distance d to the center lib of the rotor 31 from the opposing surface 34a, which is the
- 21 -plane opposed to the rotor side surface 31a among the surfaces of the permanent magnets 34. Then, the embedded amount x is given by:

x = r - d. (6) Since the rotor 31 has the above-mentioned structure, the magnetic flux generated by the permanent magnets 34 is more effectively used for the generation of the magnet torque. The rotor side surface 31a and the permanent magnets 34 are located the closest to each other at the end portions 34c, and this reduces the magnetic force lines passing between the rotor side surface 31a and the end 34c among the magnetic force lines generated by the permanent magnets 34. Thus, the stronger magnet torque is generated. In this way, the brushless motor in this embodiment can obtain the strong magnet torque in the same way as the known brushless motor.

From the viewpoint of the generation of the magnet torque, the distance L between the rotor side surface 31a and the end portion 34c is desired to be narrow. The narrower the distance between the rotor side surface 31a and the end portion 34c, the smaller the number of the magnetic force lines passing between the rotor side surface 31a and the end portion 34c among the magnetic force lines generated by the
- 22 -permanent magnets 34. The distance between the rotor side surface 31a and the end portion 34c is desired to be selected such that substantially all of the magnetic force lines generated by the permanent magnets 34 pass through the rotor side surface 31a.

On the other hand, a narrow distance between the rotor side surface 31a and the end portions 34c weakens the mechanical strength for the rotor iron core 33 to retain the permanent magnet 34. If the mechanical strength is excessively weak, the rotor iron core 33 is damaged to thereby detach the permanent magnet 34 from the rotor 31 while the rotor 31 is rotated.

The distance between the rotor side surface 31a and the end portions 34c is desirable to be selected as the minimum distance while keeping the mechanical strength at which the permanent magnet 34 is not detached while the rotor 31 is rotated. According to the experiment of the inventor, it is validated that the distance between the rotor side surface 31a and the end portion 34c can be selected so as to pass at least 95 % of the magnetic force lines generated by the magnetic pole on the opposing surface 34a through the rotor side surface 31a while keeping the necessary mechanical strength.
- 23 -The permanent magnets 34 does not face on the rotor side surface 31a, while the permanent magnets 34 are placed in the vicinity of the rotor side surface 31a. The permanent magnet 34 is embedded in the rotor iron core 33. That is, the rotor iron core 33 contains a magnetic force line inducing body 33a located between the permanent magnets 34 and the rotor side surface 31a.

The existence of the magnetic force line inducing body 33a contributes to a drop in an input voltage V of the brushless motor in this embodiment. The input voltage V is given by:

V = J6 = { (RId + (j)LgIq)2 + (RIq - U)LdId+Vc ) 2}1/2l "' (7) where R: Resistance of the armature 0): Angular frequency of the rotor rotation Id: d-axis component of the armature current I. ( Id = Ia sin (1) . ) Iq: q-axis component of the armature current l a ( Iq = Ia cos ((3) . ) Vc: Induced voltage in the armature coil by the rotation of the rotor.

The existence of the magnetic force line inducing body 33a causes a field weakening on the rotor 31.
Moreover, the existence of the magnetic force
- 24 -line inducing body 33a leads to the increase in an inductance Ld in a direct axis direction.
Accordingly, (-(oLdld+Vc) approaches 0. As is understood from the equation (7), as the (-wLdld +

Vim) is close to 0, the input voltage V becomes lower. In this way, the existence of the magnetic force line inducing body 33a results in the drop in the input voltage V of the brushless motor.

The existence of the magnetic force line inducing body 33a simultaneously contributes to the generation of the reluctance torque. That is, the brushless motor uses the magnet torque similar to that of the known brushless motor, and further uses the reluctance torque. The brushless motor in this embodiment can obtain the high torque, since the magnet torque is used at the high efficiency, and additionally the reluctance torque is used.

However, differently from the known brushless motor, the ratio occupied by the reluctance torque is low in the torque generated by the brushless motor in this embodiment. This is because the permanent magnets 34 are placed in the vicinity of the rotor side surface 31a and the volume of the magnetic force line inducing body 33a is small. The main torque generated by the brushless motor in this embodiment is the
- 25 -magnet torque. Since the generated torque is mainly the magnet torque, the torque ripple is low in the brushless motor in this embodiment.

In the brushless motor in this embodiment, the number of the permanent magnets 34, namely, the pole number P has a large influence on the property of the brushless motor in this embodiment. In the brushless motor in this embodiment, the number of the permanent magnets 34 is determined as described below so that the property is improved. The number of the permanent magnets 34 may be referred to as the pole number P.

First, the number of the permanent magnets 34 is determined to be greater than the number of the slots 9. In other words, the number of the permanent magnets 34 is determined to be greater than the number of the iron cores 10 and the number of the windings 11 since the number of the slots 9 is equal to the number of the iron cores 10 and the number of the windings 11. Thus, the magnetic circuit is uniformed to thereby suppress the torque ripple.

Moreover, the number of the permanent magnets 34 is selected from the range between 12 and 30. The validity of selecting the number of the permanent magnets 34 from the range between
- 26 -12 and 30 is discussed in the following.

At first, let us suppose that a thickness of the permanent magnets 34 is virtually 0 as shown in Fig. 8A. Here, the reason why the thickness of the permanent magnets 34 is virtually 0 is to consider the ideal case in which the permanent magnets 34 can be placed in the densest condition. The opposing surface 34a opposed to the rotor side surface 31a among the surfaces of the permanent magnets 34 constitutes an inscribed polygon of the rotor 31 on the section of the rotor 31.

Let us define the effective magnet area rate Mgc as a ratio of a sum of areas of opposing surfaces 34a of the permanent magnets 34 to an area of the rotor side surface 31a. Then, the effective magnet area rate Mgc is represented by:
Mgc = S/D * 100 (%).

Here, D = 21r/P, r: the radius of rotor 31, and P: Pole Number (Number of Permanent Magnets).

Also, b implies a width of the opposing surface 34a of the permanent magnets 34 in a circumference direction of the rotor 31. The fact that the effective magnet area rate Mgc is close
- 27 -to 100 (%) implies that a larger number of magnetic force lines generated by the permanent magnets 34 come in inter-linkage with the windings 111 - 1112.

A curved line 41 of Fig. 9 indicates the dependency of the effective magnet area rate Mgc on the pole number P. As shown in Fig. 9, the greater the pole number P, the higher the effective magnet area rate Mgc. It is substantially saturated at the pole number P of 12. From this fact, it can be understood that a magnetic flux density B of the magnetic fluxes in inter-linkage with the windings 111 - 1112 can be substantially maximized by setting the pole number P to 12 or more when the thickness of the permanent magnet 34 is assumed to be virtually 0.
However, the infinitely thin permanent magnets 34 can not be actually considered. The thickness of the permanent magnets 34 is desired to be thin, however, the thickness of the permanent magnets 34 is limited by the mechanical strength, the coercive force of the permanent magnet 34 and other factors. Also, the permanent magnet 34 cannot be in contact with the rotor side surface 31a. As mentioned above, the distance L between the ends of the permanent magnets 34 and the rotor side surface 31a is
- 28 -desired to be short. However, in order to keep the mechanical strength, it is necessary that the distance L is longer than a certain value.
Hereafter, let us consider the case in which the permanent magnet 34 has a certain thickness 1 and there is a certain distance L between the ends of the permanent magnets 34 and the rotor side surface 31a, as shown in Fig. 8B.

The width S of the opposing surface 34a is decreased by the existence of the thickness 13 of the permanent magnets 34. The fact that the permanent magnets 34 have the thickness 13 implies the reduction in a magnetic force density Be of the magnetic fluxes passing through the rotor side surface 31a.

Also, the existence of the distance L to the rotor side surface 31a from the end portion of the permanent magnet 34 causes a magnetic circuit to be generated between the opposing surfaces 34a of the two permanent magnets 34 adjacent to each other. The magnetic resistance of the magnetic circuit is smaller as the distance between the two opposing surfaces 34a is shorter. Here, as the number of the permanent magnets 34 is greater, the distance between the two opposing surfaces 34a is shorter, which leads to the smaller magnetic resistance between them.
- 29 -This implies the increase in the magnetic fluxes that do not contribute to the torque generation since it is closed within the rotor 31, if the number of the permanent magnets 34 is greater.

Due to both the effects of the effective magnet area rate Mgc and the magnetic resistance between the two opposing surfaces 34a, the magnetic force density Be of the magnetic fluxes passing through the rotor side surface 31a provides the dependency in which it becomes maximum at a certain pole number P. A curved line 42 in Fig. 9 shows the dependency on the pole number P of the magnetic force density Be of the magnetic fluxes passing through the rotor side surface 31a, when the thickness I of the permanent magnet 34 and the distance L to the rotor side surface 31a from the end portions of the permanent magnets 34 are set to the values that the applicant considers as the minimum values which can be actually set on November 8, 2000.
Here, the magnetic force density Be is standardized such that the magnetic flux density of the magnetic fluxes passing through the rotor side surface 31a is 100 under assumption that the magnet faces on the entire rotor side.

As indicated by the curved line 42 of Fig.
9, in the range in which the pole number P is 12
- 30 -or less, the magnetic force density Be of the magnetic fluxes passing through the rotor side surface 31a is sharply increased as the pole number P is greater. If the pole number P becomes greater than 12, the magnetic force density Be is almost saturated, and it has the maximum value when the pole number P is 16. If the pole number P exceeds 16, the magnetic force density Be becomes gradually smaller. The pole number P in which the magnetic force density Be exceeds 85 (arb. unit) is in the range from 12 to 30. In this way, the magnetic force density Be of the magnetic fluxes passing through the rotor side surface 31a can be increased by setting the range of the pole number P to be from 12 to 30. As the magnetic force density Be is increased, the output torque of the brushless motor is stronger correspondingly to the increase.

Also, in view of a different standpoint, an input current required to obtain a certain output torque can be reduced by setting the range of the pole number P to be from 12 to 30. As well known, the output torque T is proportional to the armature current Ia flowing through the windings 111 - 1112 and the magnetic force density B of the magnetic fluxes in inter-linkage with the windings 111 - 1112, and
- 31 -T Ia = B .

That is, B (8) As is understood from the equation (8), if the larger number of magnetic flux lines generated by the permanent magnets 34 come in inter-linkage with the windings 111 - 1112, the armature current Ia required to obtain the certain output torque is reduced. The fact that the armature current Ia can be reduced implies that a capacity of an amplifier for supplying an electric power to the brushless motor can be dropped. Such property is preferable in that the brushless motor is used as a power source for an electric car having a limit of a space.

As can be understood from the above-mentioned facts, the stronger output torque can be obtained by selecting the pole number P as being in the range from 12 to 30. Also, it is possible to reduce the armature current Ia required to obtain the certain output torque.
Selecting the pole number P as being 12 or more is also preferable in terms of dropping a quadrature axis inductance Lq. Fig. 10 shows the dependency on the pole number P of the quadrature axis inductance Lq under the condition in which the permanent magnets 34 are placed such that the
- 32 -sum of the areas of the opposing surfaces 34a is maximum for each pole number P. In the range in which the pole number P is 12 or less, the quadrature axis inductance Lq is sharply dropped when the pole number P is greater. In the range in which the pole number P is 12 or more, the degree of the drop becomes slow.

Here, as can be understood from the equation (7), the drop in the quadrature axis inductance Lq enables the drop in the input voltage V to the windings 111 - 1112. That is, the input voltage V to the windings 111 - 1112 can be extremely dropped by selecting the pole number P
as being 12 or more.

As mentioned above, from the two viewpoints of the increase in the effective magnetic force density Be and the drop in the input voltage V, it can be understood that the pole number P of the brushless motor is desired to be in the range from 12 to 30.

The brushless motor in this embodiment satisfies the above-mentioned conditions, the number of the poles being 14, and the number of the slots 9 being 12. In the brushless motor in this embodiment, the number of the poles and the numbers of the slots may be any combination besides the 14 poles and the 12 slots. However,
- 33 -from the viewpoint of the miniaturization and the higher output, it is desired to employ the structure composed of the 14 poles and the 12 slots, as described in this embodiment.

Moreover, in the brushless motor, the permanent magnets 34 are placed at positions as described below so that the property is improved.

The positions of the permanent magnets 34 are selected such that the embedded amount x satisfies the following equation:
x s D/10, (9) D = 2xr/P, r: the radius of the rotor 31, and P: the pole number (the number of the permanent magnets 34).

The small embedded amount x implies that the permanent magnets 34 and the rotor side surface 31a are closer to each other. By the way, the condition of the equation (9) has the same meaning as the establishment of the following equation:

d a r - D/10, (9') with respect to the distance d between the opposing surface 34a and the center lib of the rotor 31. The longer distance d implies that the permanent magnets 34 are further closer to the rotor side surface 31a.
- 34 -Fig. 11 shows the dependency on the embedded amount x of the armature current Ia flowing through the windings 111 - 1112 required to generate a certain torque. Fig. 11 shows a peak value of the armature current Ia. As shown in Fig. 11, the fact that x s D/10 results in the extreme drop in the armature current Ia flowing through the windings 111 - 1112.

In other words, the positions of the permanent magnets 34 are selected so as to establish the following equation:

(Lq - Ld ) / Ld s 0 . 3 . (10) Fig. 12 shows the correspondence between the embedded amount x and the (Lq - Ld) / Ld. The embedded amount x and (Lq - Ld) / Ld correspond to each other in a one-to-one relationship. The smaller the embedded amount x, the smaller the (Lq - L d ) / Ld . When x = D / 1 0 , (Lq - Ld ) / Ld = 0 . 3 .

The equation (9) corresponds to the equation (10) in a one-to-one relationship.

On the contrary, even if the structure of the rotor iron core 33 and the positions of the permanent magnets 34 are different from the above-mentioned cases, if they are selected so as to satisfy the condition of the equation (10), it is possible to obtain the effect similar to that of the case when the shape of the rotor iron core
- 35 -33 and the positions of the permanent magnets 34 are equal to those of the above-mentioned case.
Here, the following equation:

Lq - Ld Z 0, (11) preferably holds. This is because the output torque is reduced when Lq - Ld <0, as can be understood from the equation (1).

That is, it preferably satisfies the following equation:

0 s ( Lq - Ld ) / Ld s 0 . 3 (12) (Third Embodiment) A brushless motor in the third embodiment is the brushless DC motor having the structure similar to that of the second embodiment. In the brushless motor in the third embodiment, the structure of a rotor differs from those of the first and second embodiments. In particular, the structure of a rotor iron core differs from those of the first and second embodiments. The other portions in the third embodiment are equal to those of the first and second embodiments.

Fig. 13 shows the structure of the brushless motor in the third embodiment. The brushless motor in the second embodiment is provided with a rotor 31' and a stator 5. The structure of the stator 5 is equal to that
- 36 -explained in the first embodiment.

Fig. 14 is an expanded view showing a part of the rotor 31'. The rotor 31' includes a rotor iron core 33' and the permanent magnets 34. The permanent magnet 34 has the opposing surface 34a opposite to the rotor side surface 31a of the rotor=31 and the opposing surface 34b opposed to the center llb of the rotor 31. The two magnetic poles of the permanent magnet 34 are located on the opposing surfaces 34a, and 34b. The permanent magnets 34 generate the magnetic flux lines in the radius direction of the rotor 31'.

The North poles of the permanent magnets 341, 343, 345, 34,, 349, 3411, and 3413 among the permanent magnets 34 are located on the outer side in the radius direction of the rotor 31, and their South poles are located on the inner side of the rotor 31. On the other hand, the South poles of the permanent magnets 342, 34,, 346, 348, 3410, 3412, and 3414 among the permanent magnets 34 are located on the outer side in the radius direction of the rotor 31, and their North poles are located on the inner side in the radius direction of the rotor 31. That is, the two permanent magnets adjacent to each other among the permanent magnets 34 generate the magnetic force lines in the directions opposite to each
- 37 -other.

The permanent magnet 34 is placed in the vicinity of a rotor side surface 31a'. Although the permanent magnet 34 is placed in the vicinity of the rotor side surface 31a', it does not face on the rotor side surface 31a. The permanent magnet 34 is embedded in the rotor iron core 33'.
The permanent magnet 34 is substantially the rectangular parallelepiped. The rotor side surface 31a and the permanent magnet 34 are located the closest to each other at the end portion 34c.

The rotor 31' having the above-mentioned structure increases the number of the magnetic flux lines in inter-linkage with the stator 5 after passing through the rotor side surface 31a, among the magnetic flux lines generated by the permanent magnets 34.

Here, slits 33a' are formed in the rotor iron core 33'. The slits 33a' extend from the end portions 34c of the permanent magnets 34 towards a rotor side 11'. However, the slits 33a' do not reach the rotor side 11'.

The slits 33a' further reduce the number of the magnetic flux lines closed within the rotor 31', among the magnetic flux lines generated by the permanent magnets 34. Thus, the brushless
- 38 -motor in the third embodiment can obtain the strong magnet torque, similarly to the second embodiment.

Also, the rotor iron core 33' has a direct axis magnetic flux line induction body 33b' located between the permanent magnets 34 and the rotor side surface 31a. The direct axis magnetic flux line induction body 33b' extends from the rotor side surface 31a' to a direct axis (d-axis) direction of the rotor 31', and reaches the surface of the permanent magnets 34. The magnetic flux lines in the direct axis direction generated by the permanent magnets 34 pass through the direct axis magnetic flux line induction body 33b', and reach the rotor side surface 31a', and further come in inter-linkage with the stator 5.
The direct axis magnetic flux line induction body 33b' determines the direct axis inductance Ld of the rotor 31'. The direct axis inductance Ld is especially determined by a width in a circumference direction of the direct axis magnetic flux line induction body 33b'.

The width of the circumference direction of the direct axis magnetic flux line induction body 33b' is selected such that (-WLd + Vim) is substantially 0. Here, w is the angular frequency of the rotation of the rotor 31', Vc is the
- 39 -induced voltage in the windings 111 - 1112 by the rotation of the rotor. As can be understood from the equation (5), since (-wLd + Vj is selected as being substantially 0, it is possible to drop the input voltage V of the brushless motor.

Moreover, a gap 33c' is formed in the rotor iron core 33'. The gap 33c' is located between the permanent magnets 34 and the rotor side surface 31a. The gap 33c' extends in a quadrature axis (q-axis) direction. This results in the decrease in a quadrature axis inductance Lq of the rotor 31'. As can be understood from the equation (5), the decrease in the quadrature axis inductance Lq leads to the decrease in the input voltage V of the brushless motor.

In this way, in the brushless motor in the third embodiment, it is possible to further decrease the input voltage V of the brushless motor.

Even in the case of the third embodiment, similarly to the second embodiment, the positions of the permanent magnets 34 and the shape of the rotor iron core 33' are desired to be selected so as to establish the following equation:

0 s (Lq - Ld) / Ld s 0. 3. (13) Preferably, the brushless motor based on the first, second or third embodiment is used to
- 40 -drive the electric car. Fig. 15 shows the electric car including the brushless motor in the first or second embodiment. A battery 51 is installed in the electric car. The battery 51 is connected to a high voltage relay 52. The high voltage relay 52 sends a voltage to respective units of the electric car. An amplifier 53 sends a voltage to a brushless motor 50 on the basis of a movement of an accelerator pedal 54. The brushless motor based on any of the first, second and third embodiments is placed as the brushless motor 50. The brushless motor 50 drives drive wheels 57 through a transmission 55 and drive shafts 56. In the electric car including the brushless motor 50, the feature of the brushless motor 50 enables a capacity of the amplifier 53 to be reduced.

Moreover, preferably, the brushless motor based on the first, second or third embodiment is placed in the electric train. Fig. 16 shows the configuration of the electric train including the brushless motor in the embodiment. A pantograph 61 is installed in the electric train. The pantograph 61 comes in contact with a wiring 62 to which a power supply voltage is sent. Then, it sends the power supply voltage to an amplifier 63.
The amplifier 63 is connected to a controller 64.
- 41 -A throttle lever 64a is installed in the controller 64. The amplifier 63 sends an input voltage to a brushless motor 60, on the basis of a movement of the throttle lever 64a. The brushless motor based on any of the first, second and third embodiments is placed as the brushless motor 60. The brushless motor 60 drives drive wheels 67 through a transmission 65 and drive shafts 66. In the electric train including the brushless motor 60, the feature of the brushless motor 60 enables a capacity of the amplifier 63 to be reduced As mentioned above, according to the present invention, it is possible to increase the output torque of the brushless motor.

According to the present invention, it is possible to suppress the torque ripple of the brushless motor.

According to the present invention, it is possible to reduce the armature current of the brushless motor.

Also, according to the present invention, it is possible to drop the input voltage of the brushless motor.

Moreover, according to the present invention, it is possible to miniaturize the brushless motor.

Claims (17)

THE EMBODIMENTS OF THE INVENTION IN WHICH AN EXCLUSIVE PROPERTY
OR PRIVILEGE IS CLAIMED ARE DEFINED AS FOLLOWS:
1. A brushless motor comprising:

a stator having a plurality of radially extending iron cores and twelve windings for respectively generating magnetic fields in said iron cores; and a rotor having a lateral surface opposed to said stator, said rotor further comprising fourteen permanent magnets each of said permanent magnets having a shape of a substantially rectangular parallelepiped; and magnetic force line induction bodies located between said permanent magnets and said lateral surface, wherein a distance (d) between the center of said rotor and magnetic pole surfaces opposed to said lateral surface among surfaces of said permanent magnets satisfies the following equation:

d >=r - D/10, where D = 2.pi.r / P, r: radius of said rotor, and P: number of permanent magnets.
2. A brushless motor according to claim 1, wherein said rotor has holes into which said permanent magnets are inserted in an axis direction of said rotor.
3. A brushless motor according to claim 1 or 2, wherein three-phase direct currents are provided for said plurality of windings.
4. A brushless motor according to claim 1, wherein a section of said permanent magnet on a flat plane vertical to a central axis of said rotor is rectangular, wherein said rectangle has short sides and long sides longer than said short sides, and said long sides are opposed to said lateral surface.
5. A brushless motor according to claim 1, wherein the following equation:

0 <= (Lq-Ld) / Ld <= 0.3, holds where Lq: quadrature axis inductance of said rotor, and Ld: direct axis inductance of said rotor.
6. A brushless motor according to claim 1, wherein said magnetic force line inducing bodies include a direct axis magnetic force line inducing body for inducing magnetic fluxes in the direct axis direction of said rotor, and wherein a gap extending in the quadrature-axis direction of said rotor is formed in said rotor.
7. A brushless motor according to claim 6, wherein the following equation:

0 <= (Lq-Ld) / Ld < 0.3, holds where Lq: quadrature axis inductance of said rotor, and Ld: direct axis inductance of said rotor.
8. A brushless motor comprising:
a stator; and a rotor having a lateral surface opposed to said stator, wherein said stator includes:

a plurality of radially extending iron cores, and a plurality of windings for respectively generating magnetic fields in said iron cores, wherein said rotor includes:

a plurality of permanent magnets, and magnetic force line induction bodies located between said permanent magnets and said lateral surface, wherein a number of said windings is N, and a number of said permanent magnets is P, and P is greater than N, and wherein said rotor has a plurality of holes into each of which said plurality of permanent magnets are inserted in an axis direction of said rotor.
9. A brushless motor comprising:
a stator; and a rotor having a lateral surface opposed to said stator, wherein said stator includes:

a plurality of radially extending iron cores, and a plurality of windings for respectively generating magnetic fields in said iron cores, wherein said rotor includes:

a plurality of permanent magnets, and magnetic force line induction bodies located between said permanent magnets and said lateral surface, and wherein an output torque T of said brushless motor is given by a following equation:

T=p {.PHIa.cndot.Cos(.beta.)+(Lq Ld)Ia2=Sin(2.beta.)/2}, p being a half of a number of said plurality of permanent magnets, .PHI. being a maximum armature flux linkage generated by said plurality of permanent magnets, Ia being an armature current, .beta. being a phase of said armature current, Ld being a direct-axis inductance of said rotor, and Lq being a quadrature-axis inductance of said rotor, while the following equation:

Lq=Ld, does not hold.
10. A brushless motor according to claim 8, wherein three-phase direct currents are provided for said plurality of windings.
11. A brushless motor according to claim 10, wherein said plurality of windings include:

a first set of windings, and a second set of windings, and wherein said first set of three-phase windings and said second set of three-phase windings are arranged to be symmetrical with respect to a line.
12. A brushless motor comprising:
a stator; and a rotor having a lateral surface opposed to said stator, wherein said stator includes:

a plurality of radially extending iron cores, and a plurality of windings for respectively generating magnetic fields in said iron cores, wherein said rotor includes:

a plurality of permanent magnets, and magnetic force line induction bodies located between said permanent magnets and said lateral surface, wherein three-phase direct currents are provided for said plurality of windings, wherein said windings include:

a first group of three-phase windings, and a second group of three-phase windings, and wherein windings having said same phase of said first and second groups of three-phase windings are adjacent to each other in the same rotation direction, and wherein said first group of three-phase windings include:
a first set of three-phase windings, and a second set of three-phase windings, and said first set of three-phase windings and said second set of three-phase windings are arranged to be approximately geometrically symmetrical with respect to a line, said second group of three-phase windings include another first set of three-phase windings and another second set of three-phase windings, and said other first set of three-phase windings and said other second set of three-phase windings are arranged to be approximately geometrically symmetrical with respect to a line.
13. A brushless motor according to claim 8, wherein one of prime factors of said P is greater than any of prime factors of said N.
14. A brushless motor according to claim 13, wherein said prime factors of said N includes 2 and 3, and said prime factor of said P includes 2 and 7.
15. A brushless motor according to claim 8, said P
satisfies the following equation:

12 <= P <= 30.
16. A brushless motor according to claim 8, wherein said N is 12 and said P is 14.
17. A brushless motor according to claim 8, wherein a section of said permanent magnet on a flat plane vertical to a central axis of said rotor is rectangular, said rectangle has short sides and long sides longer than said short sides, and said long sides are opposed to said lateral surface.
CA2380575A 2000-06-02 2001-05-31 Brushless motor Expired - Lifetime CA2380575C (en)

Applications Claiming Priority (5)

Application Number Priority Date Filing Date Title
JP2000-166119 2000-06-02
JP2000166119A JP2001352727A (en) 2000-06-02 2000-06-02 Motor
JP2000347662A JP2002153033A (en) 2000-11-15 2000-11-15 Ipm motor
JP2000-347662 2000-11-15
PCT/JP2001/004606 WO2001095464A1 (en) 2000-06-02 2001-05-31 Brushless motor

Publications (2)

Publication Number Publication Date
CA2380575A1 CA2380575A1 (en) 2001-12-13
CA2380575C true CA2380575C (en) 2010-09-28

Family

ID=26593230

Family Applications (1)

Application Number Title Priority Date Filing Date
CA2380575A Expired - Lifetime CA2380575C (en) 2000-06-02 2001-05-31 Brushless motor

Country Status (8)

Country Link
US (1) US6853106B2 (en)
EP (1) EP1207616B1 (en)
KR (1) KR100615878B1 (en)
CN (1) CN1215634C (en)
BR (1) BRPI0106747B1 (en)
CA (1) CA2380575C (en)
MX (1) MXPA02001226A (en)
WO (1) WO2001095464A1 (en)

Families Citing this family (25)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
EP1383231B1 (en) * 2002-07-18 2017-03-01 Grundfos A/S Method for acquiring the magnetic flux, the rotor position and/or the rotation speed
JP2005224006A (en) * 2004-02-05 2005-08-18 Mitsubishi Heavy Ind Ltd Ipm rotary electric machine
JP3996919B2 (en) * 2004-08-20 2007-10-24 信越化学工業株式会社 Permanent magnet motor
TWI247472B (en) 2004-08-27 2006-01-11 Delta Electronics Inc Stator structure
KR100629335B1 (en) * 2004-10-29 2006-09-29 엘지전자 주식회사 Motor and field system manufacturing method of the same and washing machine having the same
JP4626405B2 (en) * 2005-06-01 2011-02-09 株式会社デンソー Brushless motor
US7385328B2 (en) * 2006-05-23 2008-06-10 Reliance Electric Technologies, Llc Cogging reduction in permanent magnet machines
CN101247067A (en) * 2007-02-15 2008-08-20 豪栢国际(香港)有限公司 Non-360 degree driving brushless motor
US9752615B2 (en) * 2007-06-27 2017-09-05 Brooks Automation, Inc. Reduced-complexity self-bearing brushless DC motor
US7939984B2 (en) * 2007-10-30 2011-05-10 Woodward Hrt, Inc. Lamination having tapered tooth geometry which is suitable for use in electric motor
KR101451980B1 (en) * 2008-01-22 2014-10-21 엘지전자 주식회사 BLDC motor and rotator for the same
EP2083503A3 (en) * 2008-01-22 2017-03-29 LG Electronics Inc. Brushless direct current motor
CN101499684B (en) * 2008-01-31 2016-01-27 台达电子工业股份有限公司 Motor and fan and stator structure thereof
CN201219227Y (en) * 2008-07-30 2009-04-08 无锡东元电机有限公司 Permanent magnet synchronous machine rotor
CN201204529Y (en) * 2008-08-28 2009-03-04 无锡东元电机有限公司 Permanent magnet synchronous motor
CN201294443Y (en) * 2008-12-01 2009-08-19 东元总合科技(杭州)有限公司 Permanent magnet self-startup synchronous motor rotor
CH702059A1 (en) 2009-10-23 2011-04-29 Belimo Holding Ag Brushless dc motor with power loser inhibition.
US9577503B2 (en) * 2010-05-03 2017-02-21 The Board Of Regents Of The University Of Texas System Rotating machines using trapped field magnets and related methods
CN102163902B (en) * 2011-03-23 2013-09-11 曾绍洪 Staggered multi-driving direct-current brushless motor
CN103542964B (en) * 2012-07-17 2015-12-23 耀马车业(中国)有限公司 Electric bicycle moment sensor
WO2014045445A1 (en) * 2012-09-24 2014-03-27 三菱電機株式会社 Permanent magnet-embedded electric motor
FR3067880B1 (en) * 2017-06-15 2020-07-17 Moteurs Leroy-Somer ROTATING ELECTRIC MACHINE
CN112152348B (en) * 2019-06-27 2022-01-04 台达电子工业股份有限公司 Rotor lamination and rotor assembly suitable for same
RU203977U1 (en) * 2020-08-08 2021-05-04 Сергей Сергеевич Лагутин Polyphase Synchronous Electric Motor
DE102022102313A1 (en) 2022-02-01 2023-08-03 Feaam Gmbh stator and electric machine

Family Cites Families (47)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US4358696A (en) * 1981-08-19 1982-11-09 Siemens-Allis, Inc. Permanent magnet synchronous motor rotor
IT1219228B (en) * 1988-04-21 1990-05-03 Antonino Fratta SYNCHRONOUS RELUCTANCE ELECTRICAL MACHINE EQUIPPED WITH INTRINSIC POWER SUPPLY MEANS
US5097166A (en) * 1990-09-24 1992-03-17 Reuland Electric Rotor lamination for an AC permanent magnet synchronous motor
JPH0576146A (en) * 1991-06-10 1993-03-26 Shinko Electric Co Ltd Ac servo motor
JP3028669B2 (en) * 1992-02-20 2000-04-04 ダイキン工業株式会社 Brushless DC motor
JPH05304743A (en) 1992-04-25 1993-11-16 Sayama Seimitsu Kogyo Kk Vibration motor having permanent magnet as inertial body
RU2022824C1 (en) 1992-10-13 1994-11-15 Александр Борисович Любимов Electric traction transport vehicle
JPH06156064A (en) 1992-11-30 1994-06-03 Matsushita Electric Ind Co Ltd Control and driving device of air conditioner for automobile
US5510662A (en) * 1993-05-26 1996-04-23 Kabushiki Kaisha Toshiba Permanent magnet motor
JP3353586B2 (en) 1995-03-31 2002-12-03 セイコーエプソン株式会社 Drive device for brushless DC motor
EP0729217B1 (en) * 1995-02-21 2000-01-12 Siemens Aktiengesellschaft Hybride excited synchronous machine
JP3371314B2 (en) * 1995-03-24 2003-01-27 セイコーエプソン株式会社 DC brushless motor and control device
JPH09191683A (en) 1996-01-12 1997-07-22 Matsushita Electric Ind Co Ltd Inverter
US5811904A (en) * 1996-03-21 1998-09-22 Hitachi, Ltd. Permanent magnet dynamo electric machine
JPH1023724A (en) 1996-07-03 1998-01-23 Hitachi Ltd Permanent-magnet rotary electric machine
US6133662A (en) * 1996-09-13 2000-10-17 Hitachi, Ltd. Permanent magnet dynamoelectric rotating machine and electric vehicle equipped with the same
JP3308828B2 (en) 1996-10-18 2002-07-29 株式会社日立製作所 Permanent magnet rotating electric machine and electric vehicle using the same
JPH10236687A (en) 1996-12-27 1998-09-08 Minolta Co Ltd Image reader
JP3289635B2 (en) 1997-03-17 2002-06-10 株式会社日立製作所 Permanent magnet rotating electric machine
JPH1127879A (en) 1997-07-03 1999-01-29 Shibaura Eng Works Co Ltd Brushless dc motor
JPH1189137A (en) 1997-09-05 1999-03-30 Fujitsu General Ltd Permanent magnet type motor
JPH1189134A (en) 1997-09-05 1999-03-30 Fujitsu General Ltd Permanent magnet type motor
JPH1189136A (en) 1997-09-05 1999-03-30 Fujitsu General Ltd Permanent magnet type motor
JPH1189133A (en) 1997-09-05 1999-03-30 Fujitsu General Ltd Permanent magnet type motor
JP3818338B2 (en) 1997-09-05 2006-09-06 株式会社富士通ゼネラル Permanent magnet motor
JPH1189145A (en) 1997-09-10 1999-03-30 Fujitsu General Ltd Permanent magnet type motor
JPH1198791A (en) 1997-09-16 1999-04-09 Mitsubishi Heavy Ind Ltd Brushless dc motor
JP3906882B2 (en) 1997-10-24 2007-04-18 株式会社富士通ゼネラル Permanent magnet motor
JP3906883B2 (en) 1997-10-29 2007-04-18 株式会社富士通ゼネラル Permanent magnet motor
JPH11136892A (en) 1997-10-30 1999-05-21 Fujitsu General Ltd Permanent magnet motor
JPH11243653A (en) 1998-02-23 1999-09-07 Fujitsu General Ltd Permanent magnet motor
JP3821185B2 (en) 1998-03-27 2006-09-13 株式会社富士通ゼネラル Permanent magnet motor
JPH11285186A (en) 1998-03-27 1999-10-15 Fujitsu General Ltd Permanent-magnet motor
JP3746372B2 (en) * 1998-04-16 2006-02-15 株式会社日立製作所 Permanent magnet type rotating electric machine and electric vehicle using the same
JPH11346497A (en) 1998-06-02 1999-12-14 Fujii Seimitsu Kaitenki Seisakusho:Kk Dc brushless motor and control method therefor
JP4142803B2 (en) 1998-08-20 2008-09-03 カルソニックカンセイ株式会社 Brushless motor
JP4185590B2 (en) 1998-08-20 2008-11-26 カルソニックカンセイ株式会社 Brushless motor
JP4141543B2 (en) 1998-08-26 2008-08-27 カルソニックカンセイ株式会社 Brushless motor
JP2000078784A (en) 1998-09-01 2000-03-14 Fujitsu General Ltd Permanent magnet electric motor
JP3889532B2 (en) 1998-09-07 2007-03-07 三菱電機株式会社 Built-in magnetizing method for DC brushless motor
JP2000125490A (en) 1998-10-13 2000-04-28 Fujitsu General Ltd Permanent magnet motor
JP3871006B2 (en) 1998-10-13 2007-01-24 株式会社富士通ゼネラル Permanent magnet motor
JP4102495B2 (en) 1998-11-09 2008-06-18 カルソニックカンセイ株式会社 Brushless motor
JP4190628B2 (en) 1998-11-09 2008-12-03 カルソニックカンセイ株式会社 Brushless motor
JP3301980B2 (en) 1998-12-03 2002-07-15 三洋電機株式会社 Centralized winding brushless DC motor
KR100312293B1 (en) 1998-12-28 2001-12-28 김병규 Two-phase Bi-DC Motor with Single-Hole Element
JP3595973B2 (en) 1999-01-25 2004-12-02 シャープ株式会社 Brushless DC motor and washing machine

Also Published As

Publication number Publication date
WO2001095464A1 (en) 2001-12-13
CA2380575A1 (en) 2001-12-13
CN1383602A (en) 2002-12-04
CN1215634C (en) 2005-08-17
MXPA02001226A (en) 2004-05-21
BRPI0106747B1 (en) 2016-05-10
BR0106747A (en) 2002-04-23
EP1207616A1 (en) 2002-05-22
US20020171311A1 (en) 2002-11-21
EP1207616B1 (en) 2014-11-05
US6853106B2 (en) 2005-02-08
EP1207616A4 (en) 2004-08-25
KR100615878B1 (en) 2006-08-25
KR20020052172A (en) 2002-07-02

Similar Documents

Publication Publication Date Title
CA2380575C (en) Brushless motor
US10840755B2 (en) Electric machine with q-offset grooved interior-magnet rotor and vehicle
US11979063B2 (en) Rotating electric machine
US12074477B2 (en) Rotating electrical machine system
US11962194B2 (en) Rotating electric machine
US11863023B2 (en) Rotating electrical machine
EP2099114B1 (en) Rotary electric machine and electric vehicle
JP4680442B2 (en) Motor rotor
US11368073B2 (en) Rotating electrical machine
US10958120B2 (en) Electric machine rotor for harmonic flux reduction
US7482724B2 (en) Ipm electric rotating machine
RU2231200C2 (en) Brushless electric motor
KR20220044429A (en) Electric motor having stacked different rotor segments and method for designing the same
JP3679624B2 (en) Permanent magnet rotating electric machine
US20220085671A1 (en) Electric motor having permanent magnet rotor and stator and method for designing the same

Legal Events

Date Code Title Description
EEER Examination request
MKEX Expiry

Effective date: 20210531